Reflective lcd panel

ABSTRACT

The invention provides a reflective LCD panel. The reflective LCD panel of the invention is disposed with white sub-pixel unit in the pixel unit. When the pixel electrode is disposed below the CF layer, the white sub-pixel unit is a transparent film layer and the pixel electrode is a reflective electrode, or when the white sub-pixel unit is a reflective film layer, the pixel electrode is a transparent electrode or a non-transparent electrode; when the pixel electrode is disposed above the CF layer, the white sub-pixel unit is a reflection film layer and the pixel electrode is a transparent electrode. The reflective LCD panel of the invention utilizes the combination of the white sub-pixel unit and the pixel electrode to improve the utilization of the ambient light, so as to enhance the brightness of the pixel unit and further enhance the brightness of the reflective LCD panel.

CROSS REFERENCE TO RELATED APPLICATION

This is a divisional application of co-pending U.S. patent applicationSer. No. 16/671,174, filed on Nov. 1, 2019, which is a divisionalapplication of U.S. patent application Ser. No. 15/579,946, filed onDec. 6, 2017 and now U.S. Pat. No. 10,509,282, which is a national stageof PCT Application No. PCT/CN2017/113016, filed on Nov. 27, 2017,claiming foreign priority of Chinese Patent Application No.201710814427.9, filed on Sep. 11, 2017.

BACKGROUND OF THE INVENTION 1. Field of the Invention

The present invention relates to the field of display techniques, and inparticular to a reflective liquid crystal display (LCD) panel.

2. The Related Arts

The liquid crystal display (LCD) panel provides the advantages ofthinness, low power consumption, without radiation, and is widely usedin mobile phones, PDA, digital camera, PC screens or notebook PCscreens.

Most LCD devices on the market are backlight-typed, which includes abacklight module, an LCD panel engaged to the backlight module, and afront frame fastening the LCD panel and the backlight module. Theoperation principle of the LCD panel is to place the liquid crystal (LC)molecules in two parallel glass substrates. A plurality of vertical andhorizontal small wires is disposed between the two glass substrates. TheLC molecules are controlled to change direction by powering on or off,and the light of the backlight module is refracted to produce an image.

At present, the LCD device is categorized, based on the type of lightsource, transmissive type LCD, reflective LCD, and transflective LCD.

With the rise of mobile devices and wearable applications, the demandfor thinness and power saving of display devices is also growing.Therefore, the development of low power consumption display devicebecomes increasingly important. The traditional transmissive LCD hasbeen massively produced, and the color, quality, resolution of theproducts are able to meet most of the needs. However, the LCD isrelatively high power consumption when the display is used in mobile andwearable devices, which restricts usage time.

Because reflective LCD can display with ambient light without the needfor energy-consuming backlights, the reflective LCD shows greatpotential in mobile devices and wearable display applications.

FIG. 1 shows a schematic view of a known reflective LCD panel. As shownin FIG. 1, the reflective LCD panel comprises: an upper substrate 100and a lower substrate 200 disposed opposite to each other, and a liquidcrystal layer 400 sandwiched between the upper substrate 100 and thelower substrates 200; the upper substrate 100 comprising: a first basesubstrate 110, a color filter (CF) layer 240 and a black matrix (BM)disposed on the first base substrate 110, a common electrode 120disposed on the CF layer 240 and the BM 250; the lower substrate 200comprising: a second base substrate 210, a thin film transistor (TFT)device layer 220 disposed on the second base substrate 210, and a pixelelectrode 230 disposed on the TFT device layer 220; wherein the CF layer240 comprising a transmissive red sub-pixel unit 310, a transmissivegreen sub-pixel unit 320 and a transmissive blue sub-pixel unit 330separated by the BM 250; the pixel electrode 230 is a reflectiveelectrode. The operation principle of the reflective LCD panel is thatthe ambient light passes through the CF layer 240 and the LC layer 400to reach the pixel electrode 230. Then, the pixel electrode 230 reflectsthe light and the reflected light passes again through the LC layer 400and the CF layer 240, and is emitted from the surface of the uppersubstrate 100 to realize image display. During the operation of thereflective LCD panel, ambient light passes back and forth through the CFlayer 240 and the LC layer 400, resulting in relatively large loss ofambient light and low utilization, leading to insufficient brightness ofthe display screen of the LCD panel.

To improve the utilization of the ambient light by the reflective LCDpanel, a reflective LCD panel as shown in FIG. 2 is proposed. As shownin FIG. 2, the reflective LCD panel comprises: an upper substrate 100and a lower substrate 200 disposed opposite to each other, and a liquidcrystal layer 400 sandwiched between the upper substrate 100 and thelower substrates 200; the upper substrate 100 comprising: a first basesubstrate 110 and a common electrode 120 disposed the first basesubstrate 110; the lower substrate 200 comprising: a second basesubstrate 210, a thin film transistor (TFT) device layer 220 disposed onthe second base substrate 210, a pixel electrode 230 disposed on the TFTdevice layer 220, and a CF layer 240 and a BM 250 disposed on the pixelelectrode 230; wherein the CF layer 240 comprising a reflective redsub-pixel unit 310′, a reflective green sub-pixel unit 320′ and areflective blue sub-pixel unit 330′ separated by the BM 250; the pixelelectrode 230 is a transparent electrode. Specifically, the reflectivered sub-pixel unit 310′ can reflect red light and absorb green light andblue light, the reflective green sub-pixel unit 320′ can reflect greenlight and absorbs red light and blue light, and the blue reflectivesub-pixel unit 330′ can reflect blue light and absorb red light andgreen light. The operation principle of the reflective LCD panel is thatthe ambient light passes through the LC layer 400 to reach the CF layer240, and then the CF layer 240 selectively absorbs and reflects thelight, and the reflected light passes through the LC layer 400 again andemits from the surface of the upper substrate 100 to realize imagedisplay. During the operation of the reflective LCD panel, the ambientlight passes through the CF layer 240 only once, which reduces the lossof ambient light in the CF layer 240. However, since the CF layer 240absorbs most of the spectrum and the ambient light needs to go throughthe structural layers such as the LC layer 400, the upper and loweralignment films (not shown) and the first base substrate 110 twice, theloss of ambient light is still large. Therefore, the brightness of thedisplay screen of the LCD panel still needs improvement.

SUMMARY OF THE INVENTION

The object of the present invention is to provide a reflective LCDpanel, by disposing a white sub-pixel unit in the pixel unit and usingthe white sub-pixel in collaboration with the pixel electrode toincrease the brightness of the pixel unit, leading to improving theemission brightness of the reflective LCD panel.

To achieve the above object, the present invention provides a reflectiveLCD panel, which comprises: an upper substrate and a lower substratedisposed opposite to each other, and a liquid crystal (LC) layersandwiched between the upper substrate and the lower substrate; theupper substrate comprising: a first base substrate, a common electrodedisposed on the first base substrate; the lower substrate comprising: asecond base substrate, a thin film transistor (TFT) device layerdisposed on the second base substrate, a pixel electrode disposed on theTFT device layer, and a color filter (CF) layer and a black matrix (BM)disposed on the pixel electrode;

wherein the CF layer comprising a plurality of pixel units arranged inan array, with each pixel unit comprising: a red sub-pixel unit, a greensub-pixel unit, a blue sub-pixel unit, and a white sub-pixel unitseparated by the BM; the red sub-pixel unit able to reflect red lightand absorb green light and blue light; the green sub-pixel unit able toreflect green light and absorb red light and blue light; the bluesub-pixel unit able to reflect blue light and absorb red light and greenlight;

when the white sub-pixel unit being a transparent film, the pixelelectrode being a reflective electrode; when the white sub-pixel unitbeing a reflective film, the pixel electrode being a transparentelectrode or non-transparent electrode;

when the white sub-pixel unit being a transparent film, the red light,green light and blue light able to pass through the white sub-pixelunit; when the white sub-pixel unit being a reflective film, the redlight, green light and blue light able to be reflected by the whitesub-pixel unit.

According to a preferred embodiment of the present invention, the redsub-pixel unit, the green sub-pixel unit, the blue sub-pixel unit, andthe white sub-pixel unit of the pixel unit are arranged in one of thefollowing three arrangements:

the first arrangement: the red sub-pixel unit, the green sub-pixel unit,the blue sub-pixel unit, and the white sub-pixel unit being arranged ina row from left to right;

the second arrangement: the red sub-pixel unit, the green sub-pixelunit, the blue sub-pixel unit, and the white sub-pixel unit beingarranged in a column from top to bottom;

the third arrangement: the red sub-pixel unit, the green sub-pixel unit,the blue sub-pixel unit, and the white sub-pixel unit being arranged inan upper row and a lower row; the upper row comprising: from left toright, the red sub-pixel unit and the green sub-pixel unit; the lowerrow comprising: from left to right, the blue sub-pixel unit and thewhite sub-pixel unit; wherein the red sub-pixel unit and the bluesub-pixel unit forming a column, and the green sub-pixel unit and thewhite sub-pixel unit forming a column.

According to a preferred embodiment of the present invention, the redsub-pixel unit, the green sub-pixel unit, the blue sub-pixel unit, andthe white sub-pixel unit have the same thickness;

when the pixel electrode is a reflective electrode, the pixel electrodeis made of metal; when the pixel electrode is a transparent electrode,the pixel electrode is made of a transparent conductive metal oxide; andwhen the pixel electrode is a non-transparent electrode, the pixelelectrode is made of metal.

According to a preferred embodiment of the present invention, thereflective LCD panel further comprises: a first alignment film disposedat a side of the upper substrate facing the LC layer; a second alignmentfilm disposed at a side of the lower substrate facing the LC layer, anupper polarizer disposed at a side of the upper substrate facing awayfrom the LC layer; and a lower polarizer disposed at a side of the lowersubstrate facing away from the LC layer; wherein the upper polarizer andthe lower polarizer have absorbing axes mutually perpendicular to eachother.

According to a preferred embodiment of the present invention, thereflective LCD panel further comprises: a spacer disposed between the BMand the second alignment film, the spacer and the BM are made of thesame material and formed monolithically.

The present invention also provides a reflective LCD panel, whichcomprises: an upper substrate and a lower substrate disposed opposite toeach other, and a liquid crystal (LC) layer sandwiched between the uppersubstrate and the lower substrate; the upper substrate comprising: afirst base substrate, a common electrode disposed on the first basesubstrate; the lower substrate comprising: a second base substrate, athin film transistor (TFT) device layer disposed on the second basesubstrate, a color filter (CF) layer and a black matrix (BM) disposed onthe TFT device layer, and a pixel electrode disposed on the CF layer andthe BM;

wherein the CF layer comprising a plurality of pixel units arranged inan array, with each pixel unit comprising: a red sub-pixel unit, a greensub-pixel unit, a blue sub-pixel unit, and a white sub-pixel unitseparated by the BM; the red sub-pixel unit able to reflect red lightand absorb green light and blue light; the green sub-pixel unit able toreflect green light and absorb red light and blue light; the bluesub-pixel unit able to reflect blue light and absorb red light and greenlight;

the white sub-pixel unit being a reflective film, and the pixelelectrode being a transparent electrode or non-transparent electrode;

the white sub-pixel unit being a reflective film, and the red light,green light and blue light able to be reflected by the white sub-pixelunit.

According to a preferred embodiment of the present invention, the redsub-pixel unit, the green sub-pixel unit, the blue sub-pixel unit, andthe white sub-pixel unit of the pixel unit are arranged in one of thefollowing three arrangements:

the first arrangement: the red sub-pixel unit, the green sub-pixel unit,the blue sub-pixel unit, and the white sub-pixel unit being arranged ina row from left to right;

the second arrangement: the red sub-pixel unit, the green sub-pixelunit, the blue sub-pixel unit, and the white sub-pixel unit beingarranged in a column from top to bottom;

the third arrangement: the red sub-pixel unit, the green sub-pixel unit,the blue sub-pixel unit, and the white sub-pixel unit being arranged inan upper row and a lower row; the upper row comprising: from left toright, the red sub-pixel unit and the green sub-pixel unit; the lowerrow comprising: from left to right, the blue sub-pixel unit and thewhite sub-pixel unit; wherein the red sub-pixel unit and the bluesub-pixel unit forming a column, and the green sub-pixel unit and thewhite sub-pixel unit forming a column.

According to a preferred embodiment of the present invention, the redsub-pixel unit, the green sub-pixel unit, the blue sub-pixel unit, andthe white sub-pixel unit have the same thickness; the pixel electrode ismade of metal; the pixel electrode is made of a transparent conductivemetal oxide.

According to a preferred embodiment of the present invention, thereflective LCD panel further comprises: a first alignment film disposedat a side of the upper substrate facing the LC layer; a second alignmentfilm disposed at a side of the lower substrate facing the LC layer, anupper polarizer disposed at a side of the upper substrate facing awayfrom the LC layer; and a lower polarizer disposed at a side of the lowersubstrate facing away from the LC layer; wherein the upper polarizer andthe lower polarizer have absorbing axes mutually perpendicular to eachother.

According to a preferred embodiment of the present invention, thereflective LCD panel further comprises: a spacer disposed between the BMand the pixel electrode, the spacer and the BM are made of the samematerial and formed monolithically.

The present invention also provides a reflective LCD panel, whichcomprises: an upper substrate and a lower substrate disposed opposite toeach other, and a liquid crystal (LC) layer sandwiched between the uppersubstrate and the lower substrate; the upper substrate comprising: afirst base substrate, a common electrode disposed on the first basesubstrate; the lower substrate comprising: a second base substrate, athin film transistor (TFT) device layer disposed on the second basesubstrate, a pixel electrode disposed on the TFT device layer, and acolor filter (CF) layer and a black matrix (BM) disposed on the pixelelectrode;

wherein the CF layer comprising a plurality of pixel units arranged inan array, with each pixel unit comprising: a red sub-pixel unit, a greensub-pixel unit, a blue sub-pixel unit, and a white sub-pixel unitseparated by the BM; the red sub-pixel unit able to reflect red lightand absorb green light and blue light; the green sub-pixel unit able toreflect green light and absorb red light and blue light; the bluesub-pixel unit able to reflect blue light and absorb red light and greenlight;

when the white sub-pixel unit being a transparent film, the pixelelectrode being a reflective electrode; when the white sub-pixel unitbeing a reflective film, the pixel electrode being a transparentelectrode or non-transparent electrode;

when the white sub-pixel unit being a transparent film, the red light,green light and blue light able to pass through the white sub-pixelunit; when the white sub-pixel unit being a reflective film, the redlight, green light and blue light able to be reflected by the whitesub-pixel unit.

wherein the red sub-pixel unit, the green sub-pixel unit, the bluesub-pixel unit, and the white sub-pixel unit of the pixel unit beingarranged in one of the following three arrangements:

the first arrangement: the red sub-pixel unit, the green sub-pixel unit,the blue sub-pixel unit, and the white sub-pixel unit being arranged ina row from left to right;

the second arrangement: the red sub-pixel unit, the green sub-pixelunit, the blue sub-pixel unit, and the white sub-pixel unit beingarranged in a column from top to bottom;

the third arrangement: the red sub-pixel unit, the green sub-pixel unit,the blue sub-pixel unit, and the white sub-pixel unit being arranged inan upper row and a lower row; the upper row comprising: from left toright, the red sub-pixel unit and the green sub-pixel unit; the lowerrow comprising: from left to right, the blue sub-pixel unit and thewhite sub-pixel unit; wherein the red sub-pixel unit and the bluesub-pixel unit forming a column, and the green sub-pixel unit and thewhite sub-pixel unit forming a column;

wherein the red sub-pixel unit, the green sub-pixel unit, the bluesub-pixel unit, and the white sub-pixel unit having the same thickness;

when the pixel electrode being a reflective electrode, the pixelelectrode being made of metal; when the pixel electrode beings atransparent electrode, the pixel electrode being made of a transparentconductive metal oxide; and when the pixel electrode being anon-transparent electrode, the pixel electrode being made of metal.

further comprising: a first alignment film disposed at a side of theupper substrate facing the LC layer; a second alignment film disposed ata side of the lower substrate facing the LC layer, an upper polarizerdisposed at a side of the upper substrate facing away from the LC layer;and a lower polarizer disposed at a side of the lower substrate facingaway from the LC layer; wherein the upper polarizer and the lowerpolarizer having absorbing axes mutually perpendicular to each other;

further comprising: a spacer disposed between the BM and the secondalignment film, the spacer and the BM being made of the same materialand formed monolithically.

The present invention provides the following advantages. The reflectiveLCD panel of the present invention is disposed with white sub-pixel unitin the pixel unit. When the pixel electrode is disposed below the CFlayer, the white sub-pixel unit is a transparent film layer and thepixel electrode is a reflective electrode, or when the white sub-pixelunit is a reflective film layer, the pixel electrode is a transparentelectrode or a non-transparent electrode; when the pixel electrode isdisposed above the CF layer, the white sub-pixel unit is a reflectionfilm layer and the pixel electrode is a transparent electrode. Thereflective LCD panel of the present invention utilizes the combinationof the white sub-pixel unit and the pixel electrode to improve theutilization of the ambient light, so as to enhance the brightness of thepixel unit and further enhance the brightness of the reflective LCDpanel.

BRIEF DESCRIPTION OF THE DRAWINGS

To make the technical solution of the embodiments according to thepresent invention, a brief description of the drawings that arenecessary for the illustration of the embodiments will be given asfollows. Apparently, the drawings described below show only exampleembodiments of the present invention and for those having ordinaryskills in the art, other drawings may be easily obtained from thesedrawings without paying any creative effort. In the drawings:

FIG. 1 is a schematic view showing the structure of a conventionalreflective LCD panel;

FIG. 2 is a schematic view showing the structure of another conventionalreflective LCD panel;

FIG. 3 is a schematic view showing the structure of a reflective LCDpanel provided by a first embodiment of the present invention;

FIG. 4 is a schematic view showing the structure of a reflective LCDpanel provided by a second embodiment of the present invention;

FIG. 5 is a schematic view showing the first arrangement of the pixelunit in the reflective LCD panel provided by the first and secondembodiments of the present invention;

FIG. 6 is a schematic view showing the second arrangement of the pixelunit in the reflective LCD panel provided by the first and secondembodiments of the present invention;

FIG. 7 is a schematic view showing the third arrangement of the pixelunit in the reflective LCD panel provided by the first and secondembodiments of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

To further explain the technique means and effect of the presentinvention, the following uses preferred embodiments and drawings fordetailed description.

Refer to FIG. 3. The present invention provides a reflective LCD panel,which comprises: an upper substrate 10 and a lower substrate 20 disposedopposite to each other, and a liquid crystal (LC) layer 40 sandwichedbetween the upper substrate 10 and the lower substrate 20; the uppersubstrate 10 comprising: a first base substrate 11, a common electrode12 disposed on the first base substrate 11; the lower substrate 20comprising: a second base substrate 21, a thin film transistor (TFT)device layer 22 disposed on the second base substrate 21, a pixelelectrode 23 disposed on the TFT device layer 22, and a color filter(CF) layer 24 and a black matrix (BM) 25 disposed on the pixel electrode23;

wherein the CF layer 24 comprising a plurality of pixel units 30arranged in an array, with each pixel unit comprising: a red sub-pixelunit 31, a green sub-pixel unit 32, a blue sub-pixel unit 33, and awhite sub-pixel unit 34 separated by the BM 25; the red sub-pixel unit31 able to reflect red light and absorb green light and blue light; thegreen sub-pixel unit 32 able to reflect green light and absorb red lightand blue light; the blue sub-pixel unit 33 able to reflect blue lightand absorb red light and green light;

when the white sub-pixel unit 34 being a transparent film, the pixelelectrode 23 being a reflective electrode; when the white sub-pixel unit34 being a reflective film, the pixel electrode 23 being a transparentelectrode or non-transparent electrode.

Specifically, when the white sub-pixel unit 34 is a transparent film,the red light, green light and blue light are able to pass through thewhite sub-pixel unit 34; when the white sub-pixel unit 34 is areflective film, the red light, green light and blue light are able tobe reflected by the white sub-pixel unit 34.

When the white sub-pixel unit 34 is a transparent film layer, the pixelelectrode 23 is a reflective electrode. The operation principle of thereflective LCD panel is: the white ambient light passes through the LClayer 40 to reach the red sub-pixel unit 31, the green sub-pixel unit32, and the blue sub-pixel unit 33 of the CF layer 24; the red sub-pixelunit 31, the green sub-pixel unit 32, and the blue sub-pixel unit 33 ofthe CF layer 24 perform selective absorption and reflects red light,green light, blue light, respectively; the reflected red, green and bluelight passes through the LC layer 40 again and emits from the surface ofthe upper substrate 10; the white ambient light passes through the LClayer 40 to reach the white sub-pixel 34 of the CF layer 24; the whiteambient light passes through the white sub-pixel unit 34 of the CF layer24 and is reflected by the pixel electrode 23; the reflected white lightpasses through the LC layer 40 again and emits from the surface of theupper substrate 10.

When the white sub-pixel unit 34 is a reflective film layer, the pixelelectrode 23 is a transparent electrode or a non-transparent electrode.The operation principle of the reflective LCD panel is: the whiteambient light passes through the LC layer 40 to reach the red sub-pixelunit 31, the green sub-pixel unit 32, and the blue sub-pixel unit 33 ofthe CF layer 24; the red sub-pixel unit 31, the green sub-pixel unit 32,and the blue sub-pixel unit 33 of the CF layer 24 perform selectiveabsorption and reflects red light, green light, blue light,respectively; the reflected red, green and blue light passes through theLC layer 40 again and emits from the surface of the upper substrate 10;the white ambient light passes through the LC layer 40 to reach thewhite sub-pixel 34 of the CF layer 24; the white ambient light isreflected by the white sub-pixel unit 34; the reflected white lightpasses through the LC layer 40 again and emits from the surface of theupper substrate 10.

Compared to the conventional reflective LCD panel shown in FIG. 2, thepresent invention disposes a white sub-pixel unit 34 in the pixel unit30 and uses the white sub-pixel unit 34 in collaboration with the pixelelectrode 23 to add a beam of white light in the light emitted from thepixel unit 30 so as to increase the brightness of the pixel unit 30 andthe emission brightness of the reflective LCD panel.

Specifically, the red sub-pixel unit 31, the green sub-pixel unit 32,the blue sub-pixel unit 33, and the white sub-pixel unit 34 of the pixelunit 30 can be arranged in the same row or in different rows, but allmust be in the same layer.

Specifically, the red sub-pixel unit 31, the green sub-pixel unit 32,the blue sub-pixel unit 33, and the white sub-pixel unit 34 of the pixelunit 30 are arranged in one of the following three arrangements:

As shown in FIG. 5, the first arrangement: the red sub-pixel unit 31,the green sub-pixel unit 32, the blue sub-pixel unit 33, and the whitesub-pixel unit 34 are arranged in a row from left to right.

As shown in FIG. 6, the second arrangement: the red sub-pixel unit 31,the green sub-pixel unit 32, the blue sub-pixel unit 33, and the whitesub-pixel unit 34 are arranged in a column from top to bottom.

As shown in FIG. 7, the third arrangement: the red sub-pixel unit 31,the green sub-pixel unit 32, the blue sub-pixel unit 33, and the whitesub-pixel unit 34 are arranged in an upper row and a lower row; theupper row comprises: from left to right, the red sub-pixel unit 31 andthe green sub-pixel unit 32; the lower row comprises: from left toright, the blue sub-pixel unit 33 and the white sub-pixel unit 34;wherein the red sub-pixel unit 31 and the blue sub-pixel unit 33 form acolumn, and the green sub-pixel unit 32 and the white sub-pixel unit 34form a column.

Specifically, the red sub-pixel unit 31, the green sub-pixel unit 32,the blue sub-pixel unit 33, and the white sub-pixel unit 34 have thesame thickness, or slightly different.

Specifically, when the pixel electrode 23 is a reflective electrode, thepixel electrode 23 is made of metal, preferably, aluminum (Al); when thepixel electrode 23 is a transparent electrode, the pixel electrode 23 ismade of a transparent conductive metal oxide, preferably ITO; and whenthe pixel electrode 23 is a non-transparent electrode, the pixelelectrode 23 is made of metal, preferably, aluminum (Al).

Specifically, the red sub-pixel unit 31, the green sub-pixel unit 32,the blue sub-pixel unit 33, and the white sub-pixel unit 34 are all madeof organic material.

Specifically, the BM 25 is to prevent the light from the adjacentsub-pixel units among the red sub-pixel unit 31, the green sub-pixelunit 32, the blue sub-pixel unit 33, and the white sub-pixel unit 34from mixing, and to improve purity of the light color emitted from asingle sub-pixel unit.

Specifically, the reflective LCD panel further comprises: a firstalignment film 51 disposed at a side of the upper substrate 10 facingthe LC layer 40; a second alignment film 52 disposed at a side of thelower substrate 20 facing the LC layer 40, an upper polarizer 61disposed at a side of the upper substrate 10 facing away from the LClayer 40; and a lower polarizer 62 disposed at a side of the lowersubstrate 20 facing away from the LC layer 40; wherein the upperpolarizer 61 and the lower polarizer 62 have absorbing axes mutuallyperpendicular to each other.

Moreover, the reflective LCD panel further comprises: a spacer 70disposed between the BM 25 and the pixel electrode 23, the spacer 70 isto maintain the thickness of LC box so as to prevent the thickness of LClayer 40 from changing when the LCD panel is pressed. The disposition ofthe spacer 70 will not affect the aperture ratio of the pixel unit 30,which facilitates the aperture ratio of the LCD panel.

Preferably, the spacer 70 and the BM 25 are made of the same materialand formed monolithically to save production time and cost.

The above reflective LCD panel adds a white sub-pixel unit 34 to thepixel unit 30 and disposes the pixel electrode 23 beneath the CF layer24. The white sub-pixel unit 34 is a transparent film layer and thepixel electrode 23 is a reflective electrode. Alternatively, the whitesub-pixel unit 34 is a reflective film layer and the pixel electrode 23is a transparent electrode or non-transparent electrode. The presentinvention uses the white sub-pixel unit 34 in collaboration with thepixel electrode 23 to increase the brightness of the pixel unit 30 andthe emission brightness of the reflective LCD panel.

Refer to FIG. 4. The present invention also provides a reflective LCDpanel, which comprises: an upper substrate 10 and a lower substrate 20disposed opposite to each other, and a liquid crystal (LC) layer 40sandwiched between the upper substrate 10 and the lower substrate 20;the upper substrate 10 comprising: a first base substrate 11, a commonelectrode 12 disposed on the first base substrate 11; the lowersubstrate 20 comprising: a second base substrate 21, a thin filmtransistor (TFT) device layer 22 disposed on the second base substrate21, a color filter (CF) layer 24 and a black matrix (BM) 25 disposed onthe TFT device layer22 , and a pixel electrode 23 disposed on the CFlayer 24 and the BM 25;

wherein the CF layer 24 comprising a plurality of pixel units 30arranged in an array, with each pixel unit comprising: a red sub-pixelunit 31, a green sub-pixel unit 32, a blue sub-pixel unit 33, and awhite sub-pixel unit 34 separated by the BM 25; the red sub-pixel unit31 able to reflect red light and absorb green light and blue light; thegreen sub-pixel unit 32 able to reflect green light and absorb red lightand blue light; the blue sub-pixel unit 33 able to reflect blue lightand absorb red light and green light;

the white sub-pixel unit 34 being a reflective film, the pixel electrode23 being a transparent electrode.

Specifically, when the white sub-pixel unit 34 is a reflective film, thered light, green light and blue light are able to be reflected by thewhite sub-pixel unit 34.

The operation principle of the reflective LCD panel is: the whiteambient light passes through the LC layer 40 and the pixel electrode 23to reach the red sub-pixel unit 31, the green sub-pixel unit 32, and theblue sub-pixel unit 33 of the CF layer 24; the red sub-pixel unit 31,the green sub-pixel unit 32, and the blue sub-pixel unit 33 of the CFlayer 24 perform selective absorption and reflects red light, greenlight, blue light, respectively; the reflected red, green and blue lightpasses through the LC layer 40 again and emits from the surface of theupper substrate 10; the white ambient light passes through the LC layer40 and the pixel electrode 23 to reach the white sub-pixel 34 of the CFlayer 24; the white ambient light is reflected by the white sub-pixelunit 34; the reflected white light passes through the pixel electrode 23and the LC layer 40 again and emits from the surface of the uppersubstrate 10.

Compared to the conventional reflective LCD panel shown in FIG. 2, thepresent invention disposes a white sub-pixel unit 34 in the pixel unit30 and uses the white sub-pixel unit 34 in collaboration with the pixelelectrode 23 to add a beam of white light in the light emitted from thepixel unit 30 so as to increase the brightness of the pixel unit 30 andthe emission brightness of the reflective LCD panel.

Specifically, the red sub-pixel unit 31, the green sub-pixel unit 32,the blue sub-pixel unit 33, and the white sub-pixel unit 34 of the pixelunit 30 can be arranged in the same row or in different rows, but allmust be in the same layer.

Specifically, the red sub-pixel unit 31, the green sub-pixel unit 32,the blue sub-pixel unit 33, and the white sub-pixel unit 34 of the pixelunit 30 are arranged in one of the following three arrangements:

As shown in FIG. 5, the first arrangement: the red sub-pixel unit 31,the green sub-pixel unit 32, the blue sub-pixel unit 33, and the whitesub-pixel unit 34 are arranged in a row from left to right.

As shown in FIG. 6, the second arrangement: the red sub-pixel unit 31,the green sub-pixel unit 32, the blue sub-pixel unit 33, and the whitesub-pixel unit 34 are arranged in a column from top to bottom.

As shown in FIG. 7, the third arrangement: the red sub-pixel unit 31,the green sub-pixel unit 32, the blue sub-pixel unit 33, and the whitesub-pixel unit 34 are arranged in an upper row and a lower row; theupper row comprises: from left to right, the red sub-pixel unit 31 andthe green sub-pixel unit 32; the lower row comprises: from left toright, the blue sub-pixel unit 33 and the white sub-pixel unit 34;wherein the red sub-pixel unit 31 and the blue sub-pixel unit 33 form acolumn, and the green sub-pixel unit 32 and the white sub-pixel unit 34form a column.

Specifically, the red sub-pixel unit 31, the green sub-pixel unit 32,the blue sub-pixel unit 33, and the white sub-pixel unit 34 have thesame thickness, or slightly different.

Specifically, the pixel electrode 23 is made of a transparent conductivemetal oxide, preferably ITO.

Specifically, the red sub-pixel unit 31, the green sub-pixel unit 32,the blue sub-pixel unit 33, and the white sub-pixel unit 34 are all madeof organic material.

Specifically, the BM 25 is to prevent the light from the adjacentsub-pixel units among the red sub-pixel unit 31, the green sub-pixelunit 32, the blue sub-pixel unit 33, and the white sub-pixel unit 34from mixing, and to improve purity of the light color emitted from asingle sub-pixel unit.

Specifically, the reflective LCD panel further comprises: a firstalignment film 51 disposed at a side of the upper substrate 10 facingthe LC layer 40; a second alignment film 52 disposed at a side of thelower substrate 20 facing the LC layer 40, an upper polarizer 61disposed at a side of the upper substrate 10 facing away from the LClayer 40; and a lower polarizer 62 disposed at a side of the lowersubstrate 20 facing away from the LC layer 40; wherein the upperpolarizer 61 and the lower polarizer 62 have absorbing axes mutuallyperpendicular to each other.

Moreover, the reflective LCD panel further comprises: a spacer 70disposed between the BM 25 and the second alignment film 52, the spacer70 is to maintain the thickness of LC box so as to prevent the thicknessof LC layer 40 from changing when the LCD panel is pressed. Thedisposition of the spacer 70 will not affect the aperture ratio of thepixel unit 30, which facilitates the aperture ratio of the LCD panel.

Preferably, the spacer 70 and the BM 25 are made of the same materialand formed monolithically to save production time and cost.

The above reflective LCD panel adds a white sub-pixel unit 34 to thepixel unit 30 and disposes the pixel electrode 23 above the CF layer 24.The white sub-pixel unit 34 is a reflective film layer and the pixelelectrode 23 is a transparent electrode. The present invention uses thewhite sub-pixel unit 34 in collaboration with the pixel electrode 23 toincrease the brightness of the pixel unit 30 and the emission brightnessof the reflective LCD panel.

In summary, the present invention provides a reflective LCD panel. Thereflective LCD panel of the present invention is disposed with whitesub-pixel unit in the pixel unit. When the pixel electrode is disposedbelow the CF layer, the white sub-pixel unit is a transparent film layerand the pixel electrode is a reflective electrode, or when the whitesub-pixel unit is a reflective film layer, the pixel electrode is atransparent electrode or a non-transparent electrode; when the pixelelectrode is disposed above the CF layer, the white sub-pixel unit is areflection film layer and the pixel electrode is a transparentelectrode. The reflective LCD panel of the present invention utilizesthe combination of the white sub-pixel unit and the pixel electrode toimprove the utilization of the ambient light, so as to enhance thebrightness of the pixel unit and further enhance the brightness of thereflective LCD panel.

It should be noted that in the present disclosure the terms, such as,first, second are only for distinguishing an entity or operation fromanother entity or operation, and does not imply any specific relation ororder between the entities or operations. Also, the terms “comprises”,“include”, and other similar variations, do not exclude the inclusion ofother non-listed elements. Without further restrictions, the expression“comprises a...” does not exclude other identical elements from presencebesides the listed elements.

Embodiments of the present invention have been described, but notintending to impose any unduly constraint to the appended claims. Anymodification of equivalent structure or equivalent process madeaccording to the disclosure and drawings of the present invention, orany application thereof, directly or indirectly, to other related fieldsof technique, is considered encompassed in the scope of protectiondefined by the clams of the present invention.

What is claimed is:
 1. A reflective liquid crystal display (LCD) panel,which comprises: an upper substrate and a lower substrate disposedopposite to each other, and a liquid crystal (LC) layer sandwichedbetween the upper substrate and the lower substrate; the upper substratecomprising: a first base substrate, and a common electrode disposed onthe first base substrate; the lower substrate comprising: a second basesubstrate, a thin film transistor (TFT) device layer disposed on thesecond base substrate, a color filter (CF) layer and a black matrix (BM)disposed on the TFT device layer, and a pixel electrode disposed on theCF layer and the BM; wherein the CF layer comprises a plurality of pixelunits arranged in an array, each of the plurality of pixel unitscomprising: a red sub-pixel unit, a green sub-pixel unit, a bluesub-pixel unit, and a white sub-pixel unit separated by the BM; the redsub-pixel unit reflecting red light and absorbing green light and bluelight; the green sub-pixel unit reflecting green light and absorbing redlight and blue light; the blue sub-pixel unit reflecting blue light andabsorbing red light and green light; wherein the white sub-pixel unitcomprises a reflective film and reflects red light, green light, andblue light, and the pixel electrode comprises a transparent electrodethat is disposed on the CF layer and the BM, wherein the transparentelectrode is directly disposed on red sub-pixel unit, the greensub-pixel unit, the blue sub-pixel unit, and the white sub-pixel unit ofthe CF layer, and a part of the transparent electrode is stackeddirectly on the reflective film of the white sub-pixel unit; wherein thered sub-pixel unit, the green sub-pixel unit, the blue sub-pixel unit,and the white sub-pixel unit of the pixel unit are arranged in followingarrangement: the red sub-pixel unit, the green sub-pixel unit, the bluesub-pixel unit, and the white sub-pixel unit being arranged in a columnfrom top to bottom.
 2. The reflective LCD panel as claimed in claim 1,wherein the red sub-pixel unit, the green sub-pixel unit, the bluesub-pixel unit, and the white sub-pixel unit have the same thickness;the pixel electrode is made of a transparent conductive metal oxide. 3.The reflective LCD panel as claimed in claim 1, wherein the reflectiveLCD panel further comprises: a first alignment film disposed at a sideof the upper substrate facing the LC layer; a second alignment filmdisposed at a side of the lower substrate facing the LC layer, an upperpolarizer disposed at a side of the upper substrate facing away from theLC layer; and a lower polarizer disposed at a side of the lowersubstrate facing away from the LC layer; wherein the upper polarizer andthe lower polarizer have absorbing axes mutually perpendicular to eachother.
 4. The reflective LCD panel as claimed in claim 1, wherein thereflective LCD panel further comprises: a spacer disposed between the BMand the pixel electrode, the spacer and the BM are made of the samematerial and formed monolithically.